Project ScratchDuinoRobotKit blackline

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||[https://youtu.be/1VJxK9uEw7A Arduino IDE Video] <br> [http://wiki.robbo.ru/wiki/%D0%A4%D0%B0%D0%B9%D0%BB:Black_line_analog1_zigzag.ino Download the sketch]
 
||[https://youtu.be/1VJxK9uEw7A Arduino IDE Video] <br> [http://wiki.robbo.ru/wiki/%D0%A4%D0%B0%D0%B9%D0%BB:Black_line_analog1_zigzag.ino Download the sketch]
 
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|-
|colspan=6| <center>'''<font color="red">Algorithm 2 </font>''' The robot uses '''SEVEN (FIVE, in case of USB)''' numerical values of the line sensor — these are values between  <br> two extreme values, obtained when the sensor is positioned above the white area and above the black line. <br><br>The readings of the sensor are as follows: </center>'''» 0''' means the position above the white area. Both motors are on and in full swing (255), the left-hand motor is rotating forward, the right-hand motor is rotating backward. The robot turns in place during 0.1 second. <br>'''» 1''' means the position above the white area, closer to the black line. The left-hand motor is on and in full swing (255), rotating forward, while the right-hand motor is off. The robot turns on the fly during 0.1 second. <br>'''» 2''' means the position at the border of the white and black areas, even more closer to the black line. The left-hand motor is on and in full swing (255), rotating forward, while the right-hand motor is at its half (120), rotating forward, too. The robot goes ahead and turns a bit, on the fly, during 0.1 second. <br>'''» 3''' means the position at the border of the white and black areas, already above the black line. The left-hand and the right-hand motors are on and in full swing (255), both rotating forward. The robot goes ahead during 0.1 second. <br>» The rest of the values ('''4''', '''5''', and '''6''') are mirroring the '''0''', '''1''', and '''2''' options, respectively. <center><br> The trajectory the robot follows is a smooth curve with long tangent sections, so the robot can travel all along without slowing down. <br> [[File:Line.png]]<br></center>
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|colspan=6| <center>'''<font color="red">Algorithm 2 </font>''' The robot uses '''SEVEN (FIVE, in case of USB)''' numerical values of the line sensor — these are values between  <br> two extreme values, obtained when the sensor is positioned above the white area and above the black line. <br><br>The readings of the sensor are as follows: </center>'''» 0''' means the position above the white area. Both motors are on and in full swing (255), the left-hand motor is rotating forward, the right-hand motor is rotating backward. The robot turns in place during 0.1 second. <br>'''» 1''' means the position above the white area, closer to the black line. The left-hand motor is on and in full swing (255), rotating forward, while the right-hand motor is off. The robot turns on the fly during 0.1 second. <br>'''» 2''' means the position at the border of the white and black areas, even more closer to the black line. The left-hand motor is on and in full swing (255), rotating forward, while the right-hand motor is at its half (120), rotating forward, too. The robot goes ahead and turns a bit, on the fly, during 0.1 second. <br>'''» 3''' means the position at the border of the white and black areas, already above the black line. The left-hand and the right-hand motors are on and in full swing (255), both rotating forward. The robot goes ahead during 0.1 second. <br>'''»''' The rest of the values ('''4''', '''5''', and '''6''') are mirroring the '''0''', '''1''', and '''2''' options, respectively. <center><br> The trajectory the robot follows is a smooth curve with long tangent sections, so the robot can travel all along without slowing down. <br> [[File:Line.png]]<br></center>
 
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|25–26 seconds
 
|25–26 seconds

Revision as of 15:39, 25 June 2018

Name of author (s)

User:Elena Vostrikova

Description of the ROBBO Scratch project

Trip time Sketch Power supply ROBBO Scratch Trip time Arduino IDE
Algorithm 1. The robot uses ONE numerical value of the line sensor — the AVERAGE between
two extreme values, obtained when the sensor is positioned above the white area and above the black line.
If the sensor shows a value greater than the average, then the robot turns to the left during 0.1 second
and goes forward during 0.1 second.
If the sensor shows a value less than the average,
then the robot turns to the right during 0.1 second and goes forward during 0.1 second.
The trajectory the robot follows is a zigzag.
Zigzag.png
38 seconds Black line analog1 code1.png USB ROBBO Scratch Video
Download the sketch
30 seconds To turn the robot on and off,
two touch sensors are used:
analogRead(A3) – right-hand rear sensor — ON,
analogRead(A1) — left-hand rear sensor — OFF
Download the sketch
13 seconds The high speed causes numerous errors.
At a high speed, the robot misses the turns in half the cases.
Battery 7.4V ROBBO Scratch Video
Download the sketch
11 seconds Arduino IDE Video
Download the sketch
Algorithm 2 The robot uses SEVEN (FIVE, in case of USB) numerical values of the line sensor — these are values between
two extreme values, obtained when the sensor is positioned above the white area and above the black line.

The readings of the sensor are as follows:
» 0 means the position above the white area. Both motors are on and in full swing (255), the left-hand motor is rotating forward, the right-hand motor is rotating backward. The robot turns in place during 0.1 second.
» 1 means the position above the white area, closer to the black line. The left-hand motor is on and in full swing (255), rotating forward, while the right-hand motor is off. The robot turns on the fly during 0.1 second.
» 2 means the position at the border of the white and black areas, even more closer to the black line. The left-hand motor is on and in full swing (255), rotating forward, while the right-hand motor is at its half (120), rotating forward, too. The robot goes ahead and turns a bit, on the fly, during 0.1 second.
» 3 means the position at the border of the white and black areas, already above the black line. The left-hand and the right-hand motors are on and in full swing (255), both rotating forward. The robot goes ahead during 0.1 second.
» The rest of the values (4, 5, and 6) are mirroring the 0, 1, and 2 options, respectively.

The trajectory the robot follows is a smooth curve with long tangent sections, so the robot can travel all along without slowing down.
Line.png
25–26 seconds ROBBO Scratch хуже, чем Arduino IDE
обрабатывает время движения, поэтому
количество диапазонов мы сократили до 5
и упростили движение моторов.
Они все время двигаются вперед с
разной мощностью
USB Download the sketch 18 seconds Arduino IDE Video
Download the sketch
12 seconds
At a high speed, the robot misses the turn in 4 of 5 cases.
Battery 7.4V It is important to modify the sketch coded for USB,
because at a high speed, the in-between values of the sensor
cannot be handled. Объединяем все
промежуточные значения
Download the sketch
9.5 seconds It is important to immediately modify the sketch, coded for a 5V power supply (USB).
Заменить время движения робота в поворотах со 100 до
10 milliseconds. А время движения прямо
увеличить до 200 milliseconds.
It is necessary because
at a high speed, the robot rushes too fast
along the path section where the values of the sensors are changing.
Algorithm 3 The robot uses EIGHT numerical values of the line sensor — these are values between two extreme values, obtained when the sensor
is positioned above the white area and above the black line.
The trajectory the robot follows is a line with long straight sections, and the robot can travel all along without slowing down.
Line-line.png
XX seconds
XX seconds 8.5 seconds (track record!) Arduino IDE Video
Download the sketch

Описание проезда по чёрной линии с ДВУМЯ датчиками

Сложную трассу с перекрестками, ответвлениями, "зебрами" и инверсными участками с одним датчиком проехать невозможно. При подключении двух датчиков требуется использовани специальных алгоритмов, которые автоматизируют движение робота.


XX seconds XX seconds XX seconds
Trip time Sketch Power supply ROBBO Scratch Trip time Arduino IDE
Algorithm 4. - Релейный регулятор Задача этого алгоритма - удерживать робота в положении "Оба датчика робота находятся над белой линией", т.е. слева и справа от чёрной линии. Если оба датчика попадают на черную линию, the robot останавливается
2line.png
XX seconds Eng-relay-controller-RS.png USB При питании от USB робот
останавливается на повороте,
т.к. оба датчика оказываются
на черной линии Download the sketch
XX seconds
analog0 = analogRead(A0); // Got a value from the sensor analog1
analog4 = analogRead(A4); // Got a value from the sensor analog4
limit = 50;
time1 = 200;
power = 255;

//if both sensors "see" white, the robot moves straight:
if (analog0 < limit && analog4 < limit) {
move_robbo (power, power, 0, 0, time1);
}
//if the left sensor "sees" black, the robot turns to the left:
if (analog0 > limit && analog4 < limit) {
move_robbo (0, power, 0, 0, time1);
}
//if the right sensor "sees" black, the robot turns to the right:
if (analog0 < limit && analog4 > limit) {
move_robbo (power, 0, 0, 0, time1);
}
10 seconds 7.4 V When extra powered
from the battery, the robot
cuts the sharp turning off,
because at a speed,
the sensors cannot be
above the black line both at the same time ROBBO Scratch Video
Download the sketch
XX seconds Arduino IDE Video. If the battery is run down, the robot stops at the turn.
Download the sketch - sensor readings
Download the sketch - простой релейный регулятор + ON/OFF by touch sensors
Algorithm 5 Пропорциональный регулятор Пропорциональный̆ регулятор is a device that оказывающее управляющее воздействие на объект пропорционально его отклонению от заданного состояния. Принцип действия П-регулятора основывается на том, что мы находим значение отклонения от заданного состояния, которое назовем error и обозначим буквой E. Ошибка – это разница между показаниями датчиков линии:

E = S1 – S2. To obtain the value of controlling action U, we multiply this value by a chosen ratio kp: U = kp⋅E. U is the momentum that we have to add to one motor and extract from other motor. Thus, the robot will control its position itself — that is, for turning or taxing to the required direction.

XX seconds. USB ROBBO Scratch Video
XX seconds Download the sketch
7.4 V ROBBO Scratch Video
Download the sketch
XX seconds Arduino IDE Video
Download the sketch
<center>Algorithm 6 Пропорционально-дифференциальный регулятор
USB
7.4 V ROBBO Scratch Video
Download the sketch
XX seconds Arduino IDE Video
Download the sketch
Algorithm 7 ПИД-регулятор
XX seconds USB
XX seconds Battery 7.4 V ROBBO Scratch Video
Download the sketch
XX seconds Arduino IDE Video
Download the sketch
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